Explanation: Extinction is definitively confirmed only upon the death of the last individual of a species, marking the irreversible cessation of that lineage.

Explanation: A species is considered 'functionally extinct' when its remaining population can no longer sustain itself or reproduce effectively, even if some individuals are still alive. This is distinct from absolute extinction, which requires the death of the last individual.

Explanation: Lazarus taxa are species that were presumed extinct but were later rediscovered, or whose fossil record reappears after a significant gap. They are not species reintroduced after being declared extinct, but rather those that persisted undetected or reappeared in the fossil record.

Explanation: The coelacanth, a fish previously known only from fossils dating back millions of years, serves as a prominent example of a Lazarus taxon, having been rediscovered alive in the 20th century.

Explanation: Pseudoextinction occurs when a lineage evolves into a new form or species, meaning the original classification ceases to exist but the lineage persists. True extinction involves the complete termination of a lineage.

Explanation: The dagger symbol (†), not the obelisk (obelus), is conventionally used in scientific literature to indicate that a species or taxon is extinct.

Explanation: Chains of extinction, where the loss of one species precipitates the extinction of others reliant upon it, are most prevalent when species have significant ecological dependencies, such as predator-prey or host-parasite relationships, not when they go extinct in isolation.

Explanation: Coextinction is defined as the loss of a species that occurs as a consequence of the extinction of another species upon which it depends.

Explanation: The 'extinction debt' phenomenon describes the temporal lag between environmental changes that doom a species and its eventual extinction, implying that current extinctions are often consequences of past habitat alterations or environmental shifts.

Explanation: The fundamental definition of extinction denotes the irreversible cessation of a species or organismal lineage, occurring upon the death of its final individual member.

Explanation: A species may be considered 'functionally extinct' when its remaining population is unable to reproduce effectively or recover, often due to factors like advanced age, poor health, or insufficient numbers of viable breeding pairs, even if some individuals persist.

Explanation: Lazarus taxa are defined as species that were previously thought to be extinct but were subsequently rediscovered, or those whose fossilized remains reappear in the geological record after a prolonged absence, underscoring the challenges in definitively assessing extinction.

Explanation: Pseudoextinction signifies the evolutionary transformation of a lineage into a new form or species, meaning the original classification ceases to exist but the lineage persists. True extinction, conversely, represents the complete termination of a lineage with no evolutionary continuation.

Explanation: The dagger symbol (†) is the conventional notation used in scientific literature to signify that a species or taxon is extinct.

Explanation: The phenomenon where the extinction of one species leads to the extinction of other species dependent upon it is termed coextinction, often occurring with keystone species or obligate mutualists.

Explanation: The extinction of the Haast's eagle due to the disappearance of its primary prey, the moa, exemplifies coextinction, where the loss of one species directly causes the extinction of another dependent species.

Explanation: The 'extinction debt' phenomenon describes the temporal lag between environmental changes that doom a species and its eventual extinction, implying that current extinctions are often consequences of past habitat alterations or environmental shifts.

Explanation: Prior to the 19th century, prevailing scientific and theological views generally held that species were immutable and incapable of extinction, as their disappearance would disrupt a divinely ordered natural hierarchy.

Explanation: Georges Cuvier challenged prevailing beliefs by presenting empirical evidence, derived from comparative anatomy of fossil remains, that distinct species had indeed ceased to exist, thereby establishing the modern concept of extinction.

Explanation: Jean-Baptiste Lamarck viewed species change as a gradual process in response to the environment and considered extinction to be an exceptional and rare occurrence, rather than a frequent outcome of evolution.

Explanation: Charles Darwin integrated extinction into his theory of evolution by positing it as a natural consequence of interspecific competition, whereby less adapted lineages are gradually eliminated, a process often termed background extinction.

Explanation: The 'great chain of being' concept proposed a fixed, hierarchical structure of life, implying that species were immutable and incapable of extinction, as their disappearance would create gaps in this divinely ordered system.

Explanation: Robert Hooke proposed that fossils of species unknown to his time might simply inhabit unexplored regions of the Earth, such as the deep oceans, rather than indicating complete extinction.

Explanation: Georges Cuvier challenged prevailing beliefs by presenting empirical evidence, derived from comparative anatomy of fossil remains, that distinct species had indeed ceased to exist, thereby establishing the modern concept of extinction.

Explanation: Charles Darwin integrated extinction into his theory of evolution by positing it as a natural consequence of interspecific competition, whereby less adapted lineages are gradually eliminated, a process often termed background extinction.

Explanation: Prior to the 19th century, prevailing scientific and theological views generally held that species were immutable and incapable of extinction, as their disappearance would disrupt a divinely ordered natural hierarchy.

Explanation: Robert Hooke proposed that fossils of unknown species represented organisms that inhabited unexplored regions of the Earth, such as the deep oceans, rather than indicating complete extinction.

Explanation: Paleontological estimates indicate that over five billion species have become extinct throughout Earth's history, a number far exceeding one billion.

Explanation: Current scientific estimations posit the existence of approximately 8.7 million eukaryotic species globally, representing a substantial portion of Earth's biodiversity.

Explanation: Mammoths and saber-toothed cats are cited as iconic examples of extinct animal species, representing taxa that have long since disappeared from the planet.

Explanation: The typical lifespan of a species before extinction is considerably longer than suggested, generally ranging from 1 to 10 million years from its evolutionary origin.

Explanation: The Living Planet Index monitors the abundance of global wildlife populations, not human population growth. Declines in this index serve as indicators of a biodiversity crisis.

Explanation: Paleontological estimates indicate that more than five billion species have become extinct throughout Earth's history, highlighting extinction as a fundamental and pervasive process in the evolution of life.

Explanation: Current scientific estimations posit the existence of approximately 8.7 million eukaryotic species globally. This figure represents a substantial portion of Earth's biodiversity, though it may be conservative if microbial diversity is fully accounted for.

Explanation: While non-avian dinosaurs, saber-toothed cats, and mammoths are cited as examples of extinct species, Giant Sloths are not explicitly mentioned in the provided text as such.

Explanation: The average duration of a species' existence before extinction is typically estimated to be between 1 and 10 million years, although this figure exhibits considerable variation across different taxonomic groups.

Explanation: Mass extinctions, characterized by the relatively rapid disappearance of a significant fraction of global species, are infrequent occurrences in geological history, contrasting with the more common background extinction rate.

Explanation: There is widespread scientific consensus that the current extinction rate is dramatically elevated compared to historical background rates, primarily driven by anthropogenic factors.

Explanation: A 2019 report indicated that approximately one-quarter (25%) of plant and animal species are currently threatened with extinction, not half. This figure highlights the severity of the contemporary biodiversity crisis.

Explanation: The text explicitly links climate change to the extinction of amphibians during the Carboniferous Rainforest Collapse approximately 305 million years ago.

Explanation: The Permian-Triassic event is one of the 'Big Five' mass extinctions, but it occurred approximately 250 million years ago and is known for eliminating a vast majority of species, not specifically non-avian dinosaurs, which went extinct later in the Cretaceous-Paleogene event.

Explanation: Current estimates indicate that the global species extinction rate is 100 to 1,000 times greater than the historical background rate, with projections suggesting even higher rates in the future.

Explanation: The 1982 paper by Raup and Sepkoski provided significant evidence supporting the concept of catastrophic mass extinction events, contributing to their acceptance in scientific discourse.

Explanation: Mass extinction events are distinguished by the relatively rapid disappearance of a significant fraction of Earth's species, representing major disruptions to the biosphere, and occur infrequently in geological time.

Explanation: The text explicitly links climate change to the extinction of amphibians during the Carboniferous Rainforest Collapse approximately 305 million years ago.

Explanation: Current estimates indicate that the global species extinction rate is 100 to 1,000 times greater than the historical background rate, with projections suggesting even higher rates in the future.

Explanation: Contrary to the assertion, IPBES identifies unsustainable fishing, hunting, and logging as primary drivers, not minor contributors, to the global extinction crisis, alongside habitat destruction.

Explanation: Human activities have resulted in a substantial decrease, estimated at 82%, in the biomass of wild mammals, rather than an increase. This reflects the profound impact of human actions on global fauna.

Explanation: Habitat degradation, predominantly driven by agricultural expansion, is identified as the principal anthropogenic factor contributing to contemporary species extinctions.

Explanation: Habitat degradation contributes to extinction by rendering environments toxic, diminishing resource availability, or hindering a species' competitive capacity, thereby eliminating essential ecological niches.

Explanation: While inability to adapt to diseases and interspecific competition can be natural drivers of extinction, they are not *solely* natural. Human activities, such as habitat alteration or the introduction of novel pathogens and competitors, can exacerbate these factors, making them significant anthropogenic contributors as well.

Explanation: Humans introduce species to new environments, often leading to the establishment of invasive alien species that can prey on, compete with, or degrade the habitat of native species, thereby contributing to their extinction.

Explanation: The 'overkill hypothesis' posits that the extinction of large fauna (megafauna), particularly in regions like the Americas and Australia, was primarily caused by the introduction of human hunting pressures to which these animals were not adapted.

Explanation: The primary drivers of the contemporary extinction crisis are identified as human population growth and escalating per capita consumption, which intensify pressures on global ecosystems and resources.

Explanation: The primary risk of genetic pollution lies in its potential to homogenize or out-compete native species through uncontrolled hybridization and introgression, thereby eroding unique gene pools and increasing extinction vulnerability.

Explanation: Invasive species primarily contribute to extinction by disrupting ecosystems through predation, competition for resources, disease introduction, or habitat degradation, rather than by improving native habitats.

Explanation: The Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES) identifies unsustainable fishing, hunting, and logging, alongside habitat destruction, as principal drivers of the current global extinction crisis.

Explanation: Human activities are estimated to have caused an 82% reduction in the global biomass of wild mammals, reflecting a profound impact on terrestrial fauna.

Explanation: Habitat degradation, predominantly driven by agricultural expansion, is identified as the principal anthropogenic factor contributing to contemporary species extinctions, with other factors like urbanization and resource extraction also playing significant roles.

Explanation: Habitat degradation contributes to extinction by rendering environments toxic, diminishing resource availability, or hindering a species' competitive capacity, thereby eliminating essential ecological niches.

Explanation: Interspecific competition is listed among the natural factors that can lead to species extinction, alongside environmental changes and the inability to adapt to diseases.

Explanation: The 'overkill hypothesis' posits that the extinction of large fauna (megafauna), particularly in regions like the Americas and Australia, was primarily caused by the introduction of human hunting pressures to which these animals were not adapted.

Explanation: The primary drivers of the contemporary extinction crisis are identified as human population growth and escalating per capita consumption, which intensify pressures on global ecosystems and resources.

Explanation: The primary risk of genetic pollution lies in its potential to homogenize or out-compete native species through uncontrolled hybridization and introgression, thereby eroding unique gene pools and increasing extinction vulnerability.

Explanation: The conservation status 'Extinct in the Wild (EW)' denotes species known to exist solely in captivity or in artificial environments, with no wild populations remaining.

Explanation: A 2003 review projected that climate change could commit between 15% and 37% of land species to extinction by 2050, indicating a substantial potential loss of biodiversity.

Explanation: Species with pronounced sexual dimorphism in males may face elevated extinction risk because elaborate traits selected for mate competition can compromise survival or deplete genetic diversity essential for adaptation to environmental shifts.

Explanation: A key objective of the UN's Convention on Biological Diversity plan is to conserve 30% of the Earth's land and oceans by the year 2030, alongside efforts to reduce pollution and restore ecosystems.

Explanation: Scientists advocate for species preservation based on multiple factors, including their value as genetic resources, their role in maintaining ecosystem stability, and ethical considerations regarding intrinsic biodiversity value, not solely aesthetic appeal.

Explanation: The smallpox virus is cited as an example of a successfully completed planned extinction, eradicated globally through deliberate human intervention.

Explanation: De-extinction typically involves using genetic material from preserved remains of extinct species, not solely from living relatives, to attempt cloning or genetic reconstruction.

Explanation: Cloning attempts of the Pyrenean ibex faced significant challenges and were not fully successful in establishing a viable population, highlighting the difficulties inherent in de-extinction efforts.

Explanation: A large gene pool, indicative of high genetic diversity, is associated with increased adaptability and a lower extinction risk. Conversely, reduced genetic diversity can impair a species' ability to cope with environmental changes.

Explanation: The 'extinction vortex' model illustrates a positive feedback mechanism wherein declining population size leads to reduced genetic diversity and fitness, further exacerbating population decline and increasing the probability of extinction.

Explanation: While natural disasters like asteroid impacts are potential existential threats, concerns regarding human extinction, as articulated by thinkers like Martin Rees, more frequently focus on anthropogenic factors such as climate change and technological risks, which pose significant threats to long-term human survival.

Explanation: The conservation status 'Extinct in the Wild (EW)' denotes species known to exist solely in captivity or in artificial environments, with no wild populations remaining.

Explanation: A 2003 review projected that climate change could commit between 15% and 37% of land species to extinction by 2050, indicating a substantial potential loss of biodiversity.

Explanation: Species with pronounced sexual dimorphism in males may face elevated extinction risk because elaborate traits selected for mate competition can compromise survival or deplete genetic diversity essential for adaptation to environmental shifts.

Explanation: A key objective of the UN's Convention on Biological Diversity plan is to conserve 30% of the Earth's land and oceans by the year 2030, alongside efforts to reduce pollution and restore ecosystems.

Explanation: De-extinction refers to the theoretical concept and potential scientific endeavor of reviving extinct species, often through advanced genetic and cloning techniques utilizing preserved biological material.

Explanation: The 'extinction vortex' model illustrates a positive feedback mechanism wherein declining population size leads to reduced genetic diversity and fitness, further exacerbating population decline and increasing the probability of extinction.